Your search keyword '"human pancreatic islets"' showing total 4 results

1. Fluorescein-based sensors to purify human α-cells for functional and transcriptomic analyses

Author

Sevim Kahraman, Kimitaka Shibue, Dario F De Jesus, Hyunki Kim, Jiang Hu, Debasish Manna, Bridget Wagner, Amit Choudhary, and Rohit N Kulkarni

Subjects

α-cells, pseudoislets, human pancreatic islets, diabetes, Medicine, Science, Biology (General), QH301-705.5

Abstract

Pancreatic α-cells secrete glucagon, an insulin counter-regulatory peptide hormone critical for the maintenance of glucose homeostasis. Investigation of the function of human α-cells remains a challenge due to the lack of cost-effective purification methods to isolate high-quality α-cells from islets. Here, we use the reaction-based probe diacetylated Zinpyr1 (DA-ZP1) to introduce a novel and simple method for enriching live α-cells from dissociated human islet cells with ~95% purity. The α-cells, confirmed by sorting and immunostaining for glucagon, were cultured up to 10 days to form α-pseudoislets. The α-pseudoislets could be maintained in culture without significant loss of viability, and responded to glucose challenge by secreting appropriate levels of glucagon. RNA-sequencing analyses (RNA-seq) revealed that expression levels of key α-cell identity genes were sustained in culture while some of the genes such as DLK1, GSN, SMIM24 were altered in α-pseudoislets in a time-dependent manner. In conclusion, we report a method to sort human primary α-cells with high purity that can be used for downstream analyses such as functional and transcriptional studies.

Published

2023

2. Integration of human pancreatic islet genomic data refines regulatory mechanisms at Type 2 Diabetes susceptibility loci

Author

Matthias Thurner, Martijn van de Bunt, Jason M Torres, Anubha Mahajan, Vibe Nylander, Amanda J Bennett, Kyle J Gaulton, Amy Barrett, Carla Burrows, Christopher G Bell, Robert Lowe, Stephan Beck, Vardhman K Rakyan, Anna L Gloyn, and Mark I McCarthy

Subjects

Type 2 Diabetes, human pancreatic islets, GWAS, epigenetics, Medicine, Science, Biology (General), QH301-705.5

Abstract

Human genetic studies have emphasised the dominant contribution of pancreatic islet dysfunction to development of Type 2 Diabetes (T2D). However, limited annotation of the islet epigenome has constrained efforts to define the molecular mechanisms mediating the, largely regulatory, signals revealed by Genome-Wide Association Studies (GWAS). We characterised patterns of chromatin accessibility (ATAC-seq, n = 17) and DNA methylation (whole-genome bisulphite sequencing, n = 10) in human islets, generating high-resolution chromatin state maps through integration with established ChIP-seq marks. We found enrichment of GWAS signals for T2D and fasting glucose was concentrated in subsets of islet enhancers characterised by open chromatin and hypomethylation, with the former annotation predominant. At several loci (including CDC123, ADCY5, KLHDC5) the combination of fine-mapping genetic data and chromatin state enrichment maps, supplemented by allelic imbalance in chromatin accessibility pinpointed likely causal variants. The combination of increasingly-precise genetic and islet epigenomic information accelerates definition of causal mechanisms implicated in T2D pathogenesis.

Published

2018

3. Fluorescein-based sensors to purify human α-cells for functional and transcriptomic analyses.

Author

Kahraman S, Shibue K, De Jesus DF, Kim H, Hu J, Manna D, Wagner B, Choudhary A, and Kulkarni RN

Subjects

Humans, Glucagon metabolism, Transcriptome, Insulin metabolism, Glucose metabolism, Fluoresceins metabolism, Islets of Langerhans metabolism, Glucagon-Secreting Cells metabolism, Insulin-Secreting Cells metabolism

Abstract

Pancreatic α-cells secrete glucagon, an insulin counter-regulatory peptide hormone critical for the maintenance of glucose homeostasis. Investigation of the function of human α-cells remains a challenge due to the lack of cost-effective purification methods to isolate high-quality α-cells from islets. Here, we use the reaction-based probe diacetylated Zinpyr1 (DA-ZP1) to introduce a novel and simple method for enriching live α-cells from dissociated human islet cells with ~95% purity. The α-cells, confirmed by sorting and immunostaining for glucagon, were cultured up to 10 days to form α-pseudoislets. The α-pseudoislets could be maintained in culture without significant loss of viability, and responded to glucose challenge by secreting appropriate levels of glucagon. RNA-sequencing analyses (RNA-seq) revealed that expression levels of key α-cell identity genes were sustained in culture while some of the genes such as DLK1 , GSN , SMIM24 were altered in α-pseudoislets in a time-dependent manner. In conclusion, we report a method to sort human primary α-cells with high purity that can be used for downstream analyses such as functional and transcriptional studies., Competing Interests: SK is an employee of Boehringer Ingelheim Pharmaceuticals, Inc, KS, DD, HK, JH, DM, BW, AC No competing interests declared, RK is on the Scientific Advisory Board of Novo Nordisk, Biomea and Inversago Therapeutics, (© 2023, Kahraman et al.)

Published

2023

4. Integration of human pancreatic islet genomic data refines regulatory mechanisms at Type 2 Diabetes susceptibility loci.

Author

Thurner M, van de Bunt M, Torres JM, Mahajan A, Nylander V, Bennett AJ, Gaulton KJ, Barrett A, Burrows C, Bell CG, Lowe R, Beck S, Rakyan VK, Gloyn AL, and McCarthy MI

Subjects

Chromatin metabolism, DNA Methylation, Humans, White People, Diabetes Mellitus, Type 2 genetics, Epigenesis, Genetic, Genome-Wide Association Study, Islets of Langerhans physiopathology

Abstract

Human genetic studies have emphasised the dominant contribution of pancreatic islet dysfunction to development of Type 2 Diabetes (T2D). However, limited annotation of the islet epigenome has constrained efforts to define the molecular mechanisms mediating the, largely regulatory, signals revealed by Genome-Wide Association Studies (GWAS). We characterised patterns of chromatin accessibility (ATAC-seq, n = 17) and DNA methylation (whole-genome bisulphite sequencing, n = 10) in human islets, generating high-resolution chromatin state maps through integration with established ChIP-seq marks. We found enrichment of GWAS signals for T2D and fasting glucose was concentrated in subsets of islet enhancers characterised by open chromatin and hypomethylation, with the former annotation predominant. At several loci (including CDC123, ADCY5, KLHDC5 ) the combination of fine-mapping genetic data and chromatin state enrichment maps, supplemented by allelic imbalance in chromatin accessibility pinpointed likely causal variants. The combination of increasingly-precise genetic and islet epigenomic information accelerates definition of causal mechanisms implicated in T2D pathogenesis., Competing Interests: MT, Mv, JT, AM, VN, AB, KG, AB, CB, CB, RL, SB, VR, AG No competing interests declared, MM Senior editor, eLife, (© 2018, Thurner et al.)

Published

2018